Care of Mother, Child, Adolescent (Well Clients) PDF

Summary

This document details the reproductive system, focusing on female and male reproductive anatomy and the processes involved in reproduction. It also touches on development of the reproductive anatomy in both females and males, as well as mammary glands and hormones.

Full Transcript

CARE OF MOTHER,CHILD, ADOLESCENT
(WELL CLIENTS)
The Reproductive System
Female Reproduction
Unlike males, who are able to produce sperm cells throughout their
reproductive lives, females produce a finite number of egg cells.
During early fetal development germ cells migrate into the ovaries and
differentiate into oogonia
Reproductive System
The ovaries
The ovaries are solid, ovoid
structures, about 2 cm in
length and 1 cm in width.
Like the testes, they develop
from embryonic tissue along
the posterior abdominal wall,
near the kidneys.
Accessory organs include the
uterine tubes, uterus, and
vagina
Reproductive System
Oogonia
The oogonia divide by mitosis for the
next few months and some
differentiate into primary oocytes.
By fifth month there are about 7
million primary oocytes, but most will
degenerate during the next 2 months
Reproductive System
Oogonia
Those that remain will be
surrounded by a single layer of
squamous epithelial cells (follicle
cells) called a primordial follicle.
Degeneration of primary oocytes
continues.
At birth =1million primordial
follicles
At puberty 400,000 remain
Only 400-500 will reach maturity
Reproductive System
Oogonia
Each follicle consists of an immature egg called an oocyte
 Cells around the oocyte are called:
Follicle cells (one cell layer thick)
Stimulated to mature by FSH from the pituitary gland
Granulosa cells (when more than one layer is present)
Thecal cells: Cells in the ovarian stroma
Thecal & granulosa cells work together to produce estrogen
A protective layer of glycoprotein forms around the egg called the zona
pellucida
Reproductive System
Follicle development
Primordial follicle: one layer of squamous-like follicle cells surrounds
the oocyte
Primary follicle: two or more layers of cuboidal granulosa cells
enclose the oocyte
Secondary follicle: has a fluid-filled space between granulosa cells
that coalesces to form a central antrum
Graafian follicle: secondary follicle at its most mature stage that
bulges from the surface of the ovary
Corpus luteum : ruptured follicle after ovulation
The Breasts
The breast is the tissue overlying the chest (pectoral) muscles.
Breasts are made of specialized tissue that produces milk
(glandular tissue) as well as fatty tissue.
The amount of fat determines the size of the breast.
The milk-producing part of the breast is organized into 15 to 20
sections, called lobes.
Within each lobe are smaller structures, called lobules, where milk
is produced.
The milk travels through a network of tiny tubes called ducts.
The ducts connect and come together into larger ducts, which
eventually exit the skin in the nipple.
The dark area of skin surrounding the nipple is called the areola.
The Breasts
Mammary glands
Modified sweat glands that produce milk (lactation)
Milk-secreting glands open by lactiferous ducts at the nipple
Mammary line is a thickened ridge of embryonic tissue that
extends from the axilla to the groin.
Hormones of the breasts
Prolactin from the pituitary gland stimulates
the synthesis of milk
Oxytocin from the posterior pituitary gland
stimulates milk ejection
Lymph glands - Lymph
nodes draining the
breast are located in
the axilla.
Hormones of the breasts
Prolactin from the pituitary gland stimulates
the synthesis of milk
Oxytocin from the posterior pituitary gland
stimulates milk ejection
Lymph glands - Lymph
nodes draining the
breast are located in
the axilla.
IMPORTANT TERMS
Menarche – first menstruation
Puberty – transitional stage between childhood and sexual maturity. At around
age 13.
- age at which reproductive organs become functionally active
Menopause – the cessation of menstrual cycle
Post menopausal period – it is the time of life ff. menopause
Perimenopausal – period during which menopausal change are occurring between
44 – 50 years old
Menopause – the cessation of menstrual cycle
Post menopausal period – it is the time of life ff. menopause
Perimenopausal – period during which menopausal change are occurring between
44 – 50 years old

Functions of the Male Reproductive System
The two main functions of the male reproductive system are the
production and storage of sperm and the transfer of sperm to the
female’s body during sexual intercourse.
Hormones produced in the pituitary gland stimulate the production of
testosterone
Testosterone initiates physical changes that signal maturity, including
broadening of the shoulders, development of muscles and facial and
other body hair, and deepening of the voice.

Structure of the Male Reproductive System
External structure:
1. Scrotum - a skin-covered,
highly pigmented, muscular
sack that extends from the
body behind the penis; site of
sperm production; protects
the sperm by keeping the
temperature in the testes
slightly below normal
2. Penis - the male organ of
copulation (sexual
intercourse); penetrates into
the vagina and deposit semen
into the female reproductive
tract.
3. Testes - the male gonads(the
male reproductive organs);
produce both sperm and androgens,
such as testosterone, and are
active throughout the
reproductive lifespan of the male.
A. seminiferous tubules - composed of developing sperm cells
surrounding a lumen, the hollow center of the tubule, where formed
sperm are released into the duct system of the testis
B. Sertoli Cells – elongated branching cells that secrete signaling
molecules that promote sperm production
C. Germ Cells - The least mature cells, (spermatogonia), line the
basement membrane inside the tubule; the stem cells of the testis,
that are still able to differentiate into a variety of different cell
types throughout adulthood.
Structure of the Male Reproductive System
Internal structure:
1. Epididymis: a coiled
tube attached to the
testis where newly
formed sperm continue
to mature
Internal Structure
2. vas deferens - a thick, muscular tube that is bundled together
inside the scrotum with connective tissue, blood vessels, and nerves;
site where complete maturation of sperm takes place
3. Seminal vesicles - glands that contribute approximately 60 percent
of the semen volume.
Seminal vesicle fluid contains large amounts of fructose, which is
used by the sperm mitochondria to generate ATP to allow movement
through the female reproductive tract.
4. Ejaculatory duct - a short structure formed from the ampulla of
the ductus deferens and the duct of the seminal vesicle; transport
the seminal fluid into the prostate gland.
Internal Structure
5. Prostate gland - formed of both muscular and glandular tissues;
excretes an alkaline, milky fluid to the passing seminal fluid—now
called semen
6. Bulbourethral glands (Cowper’s glands) - release a thick, salty fluid
that lubricates the end of the urethra and the vagina, and helps to
clean urine residues from the penile urethra

Spermatogenesis
Spermatogenesis is the process by which male primary sperm cells
undergo meiosis and produce a number of cells calls spermatogonia,
from which the primary spermatocytes are derived.
Each primary spermatocyte divides into two secondary
spermatocytes and each secondary spermatocyte into two
spermatids or young spermatozoa.
These develop into mature spermatozoa, also known as sperm cells.
Thus, the primary spermatocyte gives rise to two cells, the
secondary spermatocytes, which in turn produce four spermatozoa

1. Spermatocytogenesis
Mitotic division of a diploid spermatogonium that resides in the basal compartment of the
seminiferous tubules, resulting in two diploid intermediate cells called primary spermatocytes.
Each primary spermatocyte then moves into the adluminal compartment of the seminiferous
tubules, duplicates its DNA, and subsequently undergoes meiosis I to produce two haploid
secondary spermatocytes.
Secondary spermatocytes later divide into haploid spermatids. During this division, random
inclusion of either parental chromosome and chromosomal crossover both increase the genetic
variability of the gamete.
Each cell division from a spermatogonium to a spermatid is incomplete; the cells remain
connected to one another by bridges of cytoplasm to allow synchronous development. Not all
spermatogonia divide to produce spermatocytes; otherwise, the supply would run out. Instead,
certain types of spermatogonia divide to produce copies of themselves, thereby ensuring a
constant supply of gametangia to fuel spermatogenesis.
2. Spermatidogenesis
The creation of spermatids from secondary spermatocytes.
Secondary spermatocytes produced earlier rapidly enter meiosis II
and divide to produce haploid spermatids. The brevity of this stage
means that secondary spermatocytes are rarely seen in histological
preparations.
3. Spermiogenesis
spermatid begins to grow a tail and develop a thickened midpiece where the mitochondria
gather and form an axoneme.
Spermatid DNA also undergoes packaging, becoming highly condensed.
The DNA is packaged with specific nuclear basic proteins, which are subsequently replaced
with protamines during spermatid elongation.
The resultant tightly packed chromatin is transcriptionally inactive.
 The Golgi apparatus surrounds the now condensed nucleus, becoming the acrosome.
One of the centrioles of the cell elongates to become the tail of the sperm.
The non-motile spermatozoa are transported to the epididymis in testicular fluid secreted by
the Sertoli cells with the aid of peristaltic contraction. While in the epididymis, the
spermatozoa gain motility and become capable of fertilization. However, transport of the
mature spermatozoa through the remainder of the male reproductive system is achieved via
muscle contraction rather than the spermatozoon’s recently acquired motility.
Maturation takes place under the influence of testosterone,
which removes the remaining unnecessary cytoplasm and
organelles. The excess cytoplasm, known as residual bodies,
is phagocytosed by surrounding Sertoli cells in the testes.
The resulting spermatozoa are now mature but lack motility,
rendering them sterile. The mature spermatozoa are
released from the protective Sertoli cells into the lumen of
the seminiferous tubule in a process called spermiation.